New insights into what drives organ transplant rejection
Subset of cells appear to trigger rejection of skin grafts; pre-treating organs could have positive implications for face transplants
- Date:
- September 6, 2018
- Source:
- Brigham and Women's Hospital
- Summary:
- Researchers set out to understand why skin grafts have such a high rate of rejection, hoping to capitalize on new biological insights to not only explain why skin transplants provoke the immune system but also what treatments can be given to an organ prior to transplantation to decrease the likelihood of rejection.
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When it comes to transplant rejection, some organs are far trickier than others. Some transplantable organs, such as the liver, are readily accepted by the recipient's immune system, rarely triggering an immune response and rejection. But the skin is a very different matter: Skin grafts have a high rate of rejection for unknown reasons.
Investigators from Brigham and Women's Hospital set out to understand why, hoping to capitalize on new biological insights to not only explain why skin transplants provoke the immune system but also what treatments can be given to an organ prior to transplantation to decrease the likelihood of rejection. Their findings, with implications for the future of face transplantation, are published in Nature Communications.
"Our work in the lab is driven by clinical observation," said co-senior author Leonardo V. Riella, MD, PhD, medical director of the Vascularized Composite Tissue Transplant Program at BWH. "Skin grafts have such a high rate of rejection compared to other organs. We wanted to find out why."
Using a mouse model of skin transplantation, the team identified a novel, specific subset of cells in donor transplanted organs that triggered rejection. Known as CD103+ dendritic cells, this cell type appeared to play a major role in rejection. In its absence, researchers observed fewer signs that the recipient's immune system had been triggered and found that the transplanted skin survived longer.
In addition, the team was able to mitigate rejection by treating organs prior to transplantation. When skin grafts were incubated with an anti-inflammatory mycobacterial protein, the grafts survived longer after transplantation. This effect was mediated by March-1, an enzyme that can inhibit the maturation of CD103+ dendritic cells in donor grafts. In addition to these observations in mouse models, the team also tested the effect of adding the mycobacterial protein to human skin grafts, finding signs that this treatment may help prevent an immune reaction.
Pre-treating skin grafts or other organs prior to transplantation represents a new, complementary strategy for preventing organ rejection. "Today, most treatment focuses on the recipient side, using immunosuppressive drugs to try to prevent rejection," said Riella. "What we propose is a complementary strategy to tame the rejection process through direct treatment of the donor organ prior to transplantation. This could offer many benefits since we're focusing on an arm of the immune system -- innate immunity -- that immune suppressors cannot regulate."
The researchers plan to continue testing safety and effectiveness of this strategy in preclinical models and, if successful, will conduct phase 1 clinical trial in humans in the years ahead.
Funding for this work was provided by Fundação de Amparo à Pesquisa do Estado do Rio Grande do Sul (FAPERGS) Grant 11/0903-1 and Financiadora de Estudos e Projetos (FINEP) Grant 01.08.0600-00, Research Grant 12FTF120070328 from the American Heart Association, RT150078 and RT150081 from the US Department of Defense and NIH grant number RO1CA119045.
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Materials provided by Brigham and Women's Hospital. Note: Content may be edited for style and length.
Journal Reference:
- Thiago J. Borges, Naoka Murakami, Felipe D. Machado, Ayesha Murshid, Benjamin J. Lang, Rafael L. Lopes, Laura M. Bellan, Mayuko Uehara, Krist H. Antunes, Maria José Pérez-Saéz, Gabriel Birrane, Priscila Vianna, João Ismael B. Gonçalves, Rafael F. Zanin, Jamil Azzi, Reza Abdi, Satoshi Ishido, Jeoung-Sook Shin, Ana Paula D. Souza, Stuart K. Calderwood, Leonardo V. Riella, Cristina Bonorino. March1-dependent modulation of donor MHC II on CD103 dendritic cells mitigates alloimmunity. Nature Communications, 2018; 9 (1) DOI: 10.1038/s41467-018-05572-z
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